A storage container, which is for an automated storage and retrieval system (ASRS), is configured to be stacked in a stack of storage containers where an underlying storage container supports the storage container(s) positioned above. The storage container is adapted to be lifted by grippers on a lifting device such that the storage container can be lifted from above. The storage container includes a base, four sides, and four corner posts. The four sides are each hingedly connected to an edge of the base. The four corner posts are each configured to interconnect a pair of adjacent sides to each other in a horizontal direction when the sides are positioned substantially 90 degrees relative the base and relative each other.

The present invention discloses a disruptive low capital and operational cost logistics system and method that provides for fast and massive delivery of e-commerce merchandise, including same day delivery, of thousands of items and packages, in extensive geographical areas, such as whole states, countries and continents, reducing the need for building, operating, or using multiple fulfillment warehouses located near the consumers as in traditional e-commerce logistics, creating a revolution in the e-commerce industry worldwide. In a disruptive manner, the systems and methods of the present invention facilitate the logistics for e-commerce delivery processes, and also may allow at the same time reducing the use of massive quantities of cardboard packages that are used for protection and containment for e-commerce orders, being sustainably beneficial for the e-commerce market, the environment, and the consumer. This is achieved by the use of multibox packages that are configured to contain a set of products including orders from different consumers and not necessarily having individual packages for individual consumers, where such multibox packages are sorted at the origin in a Central Fulfillment Center.

A beverage container according to the present invention includes a bottom wall portion, and a side wall portion extending upward from a circumferential edge of the bottom wall portion, and due to an outer diameter of the bottom wall portion being formed smaller than an outer diameter of the side wall portion, a annular stepped portion is formed at a lower end of the side wall portion, a plurality of recessed portions and a plurality of protruding portions that are alternately arranged in a circumferential direction are formed on the stepped portion, and a width of the stepped portion is larger than a width of an upper end of the side wall portion at at least portions where the recessed portions are formed.

A mobile smart container system comprises a housing, an access component configured to secure access to a compartment within the housing when in a closed position, a communication interface configured to wirelessly receive a request to access the compartment, a perceivable output device, an electromechanical latch configured to engage with the access component to releasably lock the access component in the closed position, and a processor. The processor receives and authenticates the request to access the compartment and, in response to receiving and authenticating the request, activates the electromechanical latch to unlock the access component to make the compartment accessible, and outputs, upon actuation of the electromechanical latch, an alert via the perceivable output device to identify the smart container system.

A modular flooring system comprises a modular floor surface and a plurality of stackable, three-dimensional modular interior design components (MIDCs). The modular floor surface can comprise an array of discrete, raised, low-profile, receiving panels that can be rectangular in shape. MIDCs can be securely and interchangeably placed on any group of one or more adjacent unoccupied receiving panel and they can also be stackable, such that various different floor layouts can be created. Each of the MIDCs may comprise a lower surface recess that fits over a group of one or more adjacent raised receiving panels. A first MIDC may have an raised lip on a top surface such that the lower surface recess of a second MIDC fits over, separately and interchangeably, one (or more) of the raised receiving panels and the raised lip on the top surface of the first MIDC. The MIDCs can comprise a storage cube MIDC (square or rectangular cube) as well as specialized MIDCs, such as a commode MIDC, a sink MIDC, a cooler MIDC, and a tile MIDC, etc. In such a manner, a user of the modular flooring system could locate the MIDCs on the floor surface and/or stack them to configure a preferred layout. Moreover, the MIDCs could be rearranged later to design a new layout.

Disclosed herein are modular container systems having child-resistant containers, tray inserts and tray frames. Also disclosed are methods using the modular container systems and methods of storing substances in containers. The containers have a container base and a container cap and provide for child-resistant containers. A user can releasably remove the container cap from container base with a squeeze and lift sequence. For example, the user squeezes opposite sides of the container base, which releases a locking mechanism and allows for removal of the cap by lifting or pulling the container cap off from the container base. The components of the modular container system are modular and stackable. The modular system allow for organized, efficient, accessible and storage of the child-resistant containers. The modular container system also allows for easy counting, sorting and processing of the containers.

A modular flooring system comprises a modular floor surface and a plurality of stackable, three-dimensional modular interior design components (MIDCs). The modular floor surface can comprise an array of discrete, raised, low-profile, receiving panels that can be rectangular in shape. MIDCs can be securely and interchangeably placed on any group of one or more adjacent unoccupied receiving panel and they can also be stackable, such that various different floor layouts can be created. Each of the MIDCs may comprise a lower surface recess that fits over a group of one or more adjacent raised receiving panels. A first MIDC may have an raised lip on a top surface such that the lower surface recess of a second MIDC fits over, separately and interchangeably, one (or more) of the raised receiving panels and the raised lip on the top surface of the first MIDC. The MIDCs can comprise a storage cube MIDC (square or rectangular cube) as well as specialized MIDCs, such as a commode MIDC, a sink MIDC, a cooler MIDC, and a tile MIDC, etc. In such a manner, a user of the modular flooring system could locate the MIDCs on the floor surface and/or stack them to configure a preferred layout. Moreover, the MIDCs could be rearranged later to design a new layout.

Disclosed herein are modular container systems having child-resistant containers, tray inserts and tray frames. Also disclosed are methods using the modular container systems and methods of storing substances in containers. The containers have a container base and a container cap and provide for child-resistant containers. A user can releasably remove the container cap from container base with a squeeze and lift sequence. For example, the user squeezes opposite sides of the container base, which releases a locking mechanism and allows for removal of the cap by lifting or pulling the container cap off from the container base. The components of the modular container system are modular and stackable. The modular system allow for organized, efficient, accessible and storage of the child-resistant containers. The modular container system also allows for easy counting, sorting and processing of the containers.

A tool case, especially a carrying case, for storing and transporting a power tool. A shell structure has a shell and a second shell to form a cavity to accommodate the power tool. The first shell has a first side surface and the second shell has a second side surface. A first handle can be reversibly moved around a rotational axis between a first position for carrying the tool case and a second position, whereby the first handle extends in a first plane when in the first position and the first handle extends in a second plane when in the second position, and the first and second planes are arranged orthogonally to each other. A second handle is provided in the area of the first side surface and extends in a third plane and in the second plane, the third plane running parallel to the first plane and to the first side surface.

A container having interlocking features is provided. The container includes protrusions on the upper edges of the side wall panels and base wall panels, and notches in the runners/feet for receiving the protrusions. The runners and/or feet extend to the outer perimeter of the container so they can rest on an upper edge of a like container, and do not include a recess from the outer perimeter.